Systems and methods for shaping and energizing fluids to generate luminous fluid sculptures are disclosed herein. The disclosed methods comprise one or more steps of sculpting one or more fluids into a pattern or shape using one or more forces selected from the group consisting of mechanically generated turbulence, controlled movement through a shaped chamber, application of a magnetic field, vibration, and gravity to generate one or more sculpted fluids, and one or more steps of energizing the fluids using one or more sources of nonvisible energy selected from the group consisting of chemicals, heat, electrical current, and nonvisible electromagnetic radiation so that the fluids emit visible light. The color of the visible light emitted may be controlled by modulating various color-control factors. The methods comprise at least two non-simultaneous steps, where the non-simultaneous steps may be any combination of sculpting and energizing steps, to generate dynamic luminous fluid sculptures.

Aspects of the invention are directed to systems and apparatuses for efficiently burning fuels. According to one aspect of the invention, apparatus for efficiently burning hydrocarbons includes a housing having a first opening for receiving a fuel, a second opening for expelling the fuel, and a tubular passageway extending between the first opening and the second opening. The tubular passageway includes a central region and an outer region surrounding the central region. The apparatus also includes a plurality of magnets disposed within the passageway. Each of the magnets has a spherical or an ovoid shape. The plurality of magnets define void spaces for passing the fuel such that a central flow rate of the fuel in the central region of the passageway is equivalent to the an outer flow rate of the fuel in an outer region of the passageway.

According to an embodiment, a fired heater includes a fuel and combustion air source configured to output fuel and combustion air into a combustion volume, the combustion volume including a combustion volume wall defining a lateral extent separate from an exterior volume. According to an embodiment, the fired heater includes a boiler heater and the combustion volume wall comprises a combustion pipe defining a lateral extent of the combustion volume, the combustion pipe being disposed to separate the combustion volume from a water and steam volume. The fired heater includes a mixing tube aligned to receive the fuel and combustion air from the fuel and combustion air source. The mixing tube may be separated from the combustion volume wall by a separation volume. The fired heater includes a bluff body flame holder aligned to receive a fuel and combustion air mixture from an outlet end of the mixing tube. The bluff body flame holder may be configured to hold a combustion reaction for heating a combustion volume wall. The combustion volume wall may include a combustion pipe. The combustion pipe may be configured to heat the water in the water and steam volume.

A combustion simulation system is provided. The combustion simulation system can be performed using a computing device operated by a computer user or artist. The computer-implemented method of simulating a combustion process includes receiving a set of data representing a fluid flow. The fluid flow can include combustion precursors. The method includes simulating a chemical reaction representing simulated combustion of these precursors generating combustion byproducts. The method can include determining a change in temperature of the combustion byproducts due to the chemical reaction, determining a change in molar mass of the combustion byproducts due to the chemical reaction, determining a divergence of the combustion byproducts based on a combination of the change in the temperature and the change in molar mass, and generating data structures of the simulated combustion based on values of the fluid flow.

A combustion chamber assembly unit for a fuel-operated vehicle heater includes a combustion chamber housing, a combustion chamber formed in the combustion chamber housing, an evaporator medium for the absorption of liquid fuel and for the discharge of fuel vapor into the combustion chamber, and a heating/ignition device for heating the evaporator medium or/and for igniting a mixture of fuel and combustion air formed in the combustion chamber. The heating/ignition device includes at least one radiation source for the emission of electromagnetic radiation into the combustion chamber and at least one absorption body for the absorption of electromagnetic radiation emitted into the combustion chamber.

A gas combustor having function of adjusting combusting angle includes: a fixed housing having a top end thereof transversally formed with a rod hole; and a rotary housing pivoted with the fixed housing, where one side of the rotary housing is formed with a shaft hole having a plurality of annularly-arranged teeth slots for receiving a locking mechanism having an unlocking press button, a connection rod extrudes from an inner surface of the unlocking press button to pass the shaft hole, be sleeved with a stretch spring and enter the rod hole, the connection rod is connected to a passive member in the fixed housing, the passive member has at least one convex tooth protruding toward the plurality of teeth slots, and each of the at least one convex tooth is to be inserted and positioned in one of the teeth slots to form a locked status.

A combustion system such as a furnace or boiler includes a perforated reaction holder configured to hold a combustion reaction that produces very low oxides of nitrogen (NOx).

A combustion simulation system is provided. The combustion simulation system can be performed using a computing device operated by a computer user or artist. The computer-implemented method of simulating a combustion process includes receiving a set of data representing a fluid flow. The fluid flow can include combustion precursors. The method includes simulating a chemical reaction representing simulated combustion of these precursors generating combustion byproducts. The method can include determining a change in temperature of the combustion byproducts due to the chemical reaction, determining a change in molar mass of the combustion byproducts due to the chemical reaction, determining a divergence of the combustion byproducts based on a combination of the change in the temperature and the change in molar mass, and generating data structures of the simulated combustion based on values of the fluid flow.

A burner system and a retrofit flame control system for an existing burner system are disclosed. The burner system may include burner components, electrodynamic components, and a data interface. The data interface may receive a command for controlling the burner components and prepare a command for controlling the electrodynamic components at least partially based on the command for controlling the burner components.

This invention is intended to produce more energy during the combustion of fuels (solid, liquid or gas). This is achieved by separating the electrons and the cations which are produced at the very beginning of the phenomenon of combustion. This way of making conducts to more violent shocks between the cations (C+++; H+) and the anions (O−−); thus more energy.